Current Approaches and Therapeutic Strategies for Hypothalamic Syndrome in Patients with Childhood-onset Craniopharyngioma
PDF
Cite
Share
Request
Review
VOLUME: 18 ISSUE: 2
P: 186 - 202
June 2026

Current Approaches and Therapeutic Strategies for Hypothalamic Syndrome in Patients with Childhood-onset Craniopharyngioma

J Clin Res Pediatr Endocrinol 2026;18(2):186-202
1. University Children’s Hospital Carl von Ossietzky Universität, Klinikum Oldenburg AöR, Department of Pediatrics and Pediatric Hematology/Oncology, Oldenburg, Germany
No information available.
No information available
Received Date: 10.12.2025
Accepted Date: 15.12.2025
Online Date: 01.07.2026
Publish Date: 01.07.2026
E-Pub Date: 15.01.2026
PDF
Cite
Share
Request

ABSTRACT

Patients diagnosed with craniopharyngioma often experience rapid and pronounced weight gain that can progress to severe hypothalamic obesity. This phenomenon is predominantly attributed to disruption of critical hypothalamic regulatory circuits, caused either by direct tumor infiltration or by treatment-related injury. Hypothalamic obesity is best conceptualized within the broader framework of hypothalamic syndrome, a complex clinical disorder encompassing multiple neuroendocrine deficits, impairments in circadian homeostasis, dysregulation of hunger, satiety, and thirst mechanisms, disturbances in thermoregulatory control, and a wide range of cognitive, sleep-related, and psychosocial abnormalities. Hypothalamic syndrome may also develop secondary to nonmalignant parasellar pathologies, including germ cell tumors, gliomas, Rathke’s cleft cyst, and Langerhans cell histiocytosis, as well as traumatic hypothalamic injury following traumatic brain insult. Long-term prognosis is frequently poor, driven by elevated risks of metabolic syndrome, cardiovascular disease, diminished health-related quality of life, and increased rates of premature mortality. Management remains particularly challenging. Recently, a personalized and risk-stratified therapeutic framework has been proposed to guide clinical decision-making and optimize outcomes. Several pharmacologic interventions, such as centrally acting stimulants, glucagon-like peptide-1 receptor agonists, and the melanocortin-4 receptor agonist setmelanotide, have demonstrated potential in promoting weight reduction. Bariatric surgery may also yield clinical benefit; however, the use of irreversible procedures in pediatric populations presents substantial ethical and legal challenges. There remains an urgent need for therapeutic strategies that emphasize preservation of hypothalamic structure and function, alongside continued research into targeted and emerging interventions for more effective management of hypothalamic syndrome.

Keywords:
Craniopharyngioma, obesity, metabolic syndrome, quality of life, hypothalamus, sequelae

Introduction

Craniopharyngiomas (CPs) (1) are embryonic neoplasms exhibiting low-grade histological malignancy. Their annual incidence is estimated at 0.5-2.0 newly diagnosed cases per million individuals (2, 3). In the 2021 World Health Organization classification of central nervous system tumors, adamantinomatous CP (aCP) and papillary CP (pCP) were formally designated as two distinct pathological subtypes (4). aCP predominantly occur in children and adolescents, whereas pCP almost exclusively arise in adults. Long-term prognosis is frequently compromised by tumor- and/or treatment-related injury to hypothalamic structures, which may lead to hypothalamic syndrome. Consequently, CP represents a prototypical disorder underlying hypothalamic dysfunction.

Molecular Pathology

In aCP, activating mutations in CTNNB1 induce β-catenin accumulation and pathological activation of the WNT signaling cascade. Conversely, pCP is driven by the BRAF-V600E mutation, resulting in constitutive MAPK/ERK pathway activation. Recent evidence supports a senescence-mediated pathogenic mechanism in aCP. Senescent epithelial cells secrete pro-inflammatory and trophic factors [the senescence-associated secretory phenotype (SASP)], generating a tumor-supportive microenvironment through paracrine activity. Translational advances have facilitated the clinical application of BRAF/MEK inhibition in pCP, with early studies demonstrating substantial therapeutic efficacy. In parallel, pharmacological strategies targeting SASP mediators or selectively eliminating senescent cells (senolytic therapies) are under investigation for aCP (5).

Morbidity and Mortality

Patients with CP experience overall mortality rates that are three- to fivefold higher than those in the general population (6). Reported survival in pediatric cohorts ranges from 83% to 96% at 5 years (7), 65% to 100% at 10 years (8), and averages approximately 62% at 20 years of follow-up. While some studies suggest that younger patients demonstrate superior long-term survival, others indicate more favorable outcomes in older individuals. Findings regarding sex differences remain inconsistent: several reports describe increased mortality in female patients (6), whereas others observed no significant sex-related disparities. Late mortality is frequently linked to tumor- or treatment-related complications, including disease progression or recurrence, persistent hypothalamic dysfunction, endocrine insufficiencies, seizures, cerebrovascular events, and metabolic consequences, such as nonalcoholic fatty liver disease, which may evolve into cirrhosis (8, 9). A recent review emphasized substantial long-term morbidity, citing standardized overall mortality ratios between 2.88 and 9.28. Cardiovascular mortality was 3- to 19-fold higher in CP patients than in the general population, with the highest risk observed in female patients (10). In childhood-onset (CO) CP, better baseline performance status has been associated with improved 10-year survival. The prognostic relevance of hydrocephalus at diagnosis remains debated (11). Importantly, Sterkenburg et al. (12) reported significantly reduced 20-year survival among patients with hypothalamic involvement and hypothalamic obesity. Conversely, the extent of surgical resection did not influence 20-year progression-free survival, reinforcing the view that aggressive gross-total resection does not confer a survival benefit with respect to preventing tumor recurrence in this population.

Hypothalamus and Hypothalamic Syndrome

The hypothalamus is a small yet phylogenetically conserved neuroendocrine center composed of multiple nuclei that coordinate essential physiological processes. It acts as a central integrator, governing pituitary hormonal output and influencing the autonomic nervous system, as well as modulating behavior through connections with other brain regions, including the frontal cortex. Hypothalamic disruption can produce a broad clinical phenotype encompassing (morbid) obesity (13), cachexia (14), hypopituitarism, adipsia, dysregulation of thermoregulation and circadian rhythms (15, 16), reduced energy expenditure (17), and behavioral abnormalities (18).

The term hypothalamic syndrome refers to the constellation of symptoms arising from structural or functional compromise of hypothalamic nuclei. Although CPs constitute a leading cause, other etiologies include germ cell tumors, gliomas, Rathke’s cleft cysts, Langerhans cell histiocytosis, and specific neurodevelopmental disorders such as Prader-Willi syndrome (PWS) and septo-optic dysplasia, as well as traumatic brain injury (19). Importantly, hypothalamic syndrome encompasses a broader construct than hypothalamic obesity alone and varies considerably between individuals. According to van Santen et al. (20), five major clinical domains characterize hypothalamic syndrome in CO CP: disordered eating, behavioral abnormalities, sleep disturbances, thermoregulatory dysfunction, and endocrine impairments.

Management of Hypothalamic Syndrome

An individualized management approach for CO CP patients with hypothalamic syndrome was initially proposed by van Iersel et al. (21). A recent update shifts emphasis from isolated obesity treatment to addressing the full spectrum of hypothalamic dysfunction (22, 23) (Figure 1). This more comprehensive framework aims to improve not only body mass index (BMI) but also overall vitality and daily functioning. Findings by van Schaik et al. (26) underscore the benefits of centralized care (24, 25): following national centralization of CP treatment in the Netherlands, the incidence of hypothalamic obesity in children with CP fell from 33% to 12%.

Hypothalamic and Pituitary Function

Hypothalamic nuclei exert regulatory control over the pituitary gland by producing releasing hormones. Damage to hypothalamic structures may therefore lead to multiple pituitary hormone deficiencies, including hypogonadotropic hypogonadism, growth hormone (GH) deficiency, central hypothyroidism, and adrenocorticotropic hormone (ACTH) deficiency. In addition, the hypothalamus secrets arginine vasopressin (AVP), which is stored and released from the posterior pituitary gland.

GH Deficiency

Insufficient endocrine replacement therapy can result in severe consequences, such as impaired growth (27). GH replacement in patients with confirmed GH deficiency does not increase the risk of CP recurrence or progression (28). Unlike malignant tumors, no mandatory waiting period is required between completion of oncological therapy and initiation of GH treatment in CP. Early GH replacement may assist with weight regulation and improve quality of life (QoL) (29). A recent consensus statement from the Growth Hormone Research Society concluded that GH therapy is safe in CP (28). Although GH does not correct hypothalamic obesity, it supports healthier body composition and reduces metabolic complications (29).

Adrenocorticotropin Deficiency

ACTH deficiency, typically resulting from tumor-associated damage or therapeutic interventions, necessitates hydrocortisone replacement with stress-adjusted dosing. Cortisol deficiency may clinically present with headaches, nausea, or reduced stress tolerance, and can progress to life-threatening adrenal crisis. Excessive glucocorticoid administration increases obesity risk. While perioperative corticosteroid therapy may cause short-term weight gain, it has not been linked to long-term obesity (30). Physiological dosing of hydrocortisone substitution should not elevate obesity risk.

Hypothyroidism

Central hypothyroidism may be overlooked if free thyroxine (T4) levels remain in the lower half of the reference interval. A reduction of >20% in free T4 should prompt suspicion and consideration of levothyroxine therapy (31). Replacement should maintain free T4 concentrations in the mid-to-upper reference range. Insufficient replacement may contribute to weight gain, emphasizing the need for optimal dosing.

Gonadotropin Deficiency

Gonadotropin deficiency often requires induction of puberty and, in some cases, assisted reproductive techniques (32). Adults treated for CP in childhood show high rates of psychosexual dysfunction and reduced sexual activity (32). In males, low testosterone is associated with adverse metabolic profiles and increased mortality risk. Adequate testosterone replacement can improve body composition through reduction of fat mass and increase in lean mass.

Oxytocin

Oxytocin deficiency in CP arises primarily from hypothalamic injury, contributing to hypothalamic syndrome. Compared with healthy individuals, CP patients show reduced basal and stimulated salivary oxytocin levels (33, 34, 35, 36). Lower levels correlate with increased anxiety and impaired social cognition. Individuals with anterior hypothalamic lesions exhibit the lowest oxytocin concentrations and respond most favorably to single-dose intranasal oxytocin compared with patients with posterior lesions or healthy controls (34, 35). These data indicate potential for oxytocin-based interventions to treat neuropsychological symptoms of hypothalamic syndrome (37).

AVP Deficiency (AVP-D)

AVP-D commonly results from posterior hypothalamic injury and predisposes to hypothalamic obesity. It therefore serves both as a marker of hypothalamic damage and an independent risk factor for obesity and reduced QoL (38). When thirst regulation is also impaired, adipsic AVP-D may occur, carrying substantial risk for sodium imbalance and systemic instability.

Sleep Disorders

Children with CP and hypothalamic syndrome may develop primary hypothalamic sleep disturbances, including hypersomnia (15), narcolepsy (39) and circadian rhythm dysregulation (16). Secondary sleep problems can arise from tumor therapy, severe obesity, or visual impairment. These include psychosocial stressors, obstructive sleep apnea, poorly controlled AVP-D with nocturia, and other comorbidities. Sleep-wake disruption and circadian disturbances are hallmark manifestations of hypothalamic syndrome (40). Hypersomnia is defined by excessive daytime sleepiness (EDS) despite adequate nighttime sleep. Affected individuals often struggle to remain awake during daily activities (40). In a cohort of 115 CO CP patients, Müller et al. (39) reported EDS in 30% of cases, including hypersomnia and secondary narcolepsy. Central stimulants such as modafinil or methylphenidate improved alertness and daily functioning (39).

Temperature Regulation

Thermoregulation is governed by interconnected hypothalamic circuits, including the arcuate nucleus (thermogenesis), the preoptic area-dorsomedial hypothalamic circuit (temperature sensing), and the ventromedial hypothalamus (cold-induced thermogenesis) (41). Hypothalamic injury can impair these pathways, resulting in hypothermia (<36 °C) or hyperthermia (>37.5 °C) (42, 43). Some patients maintain normal core temperatures but experience subjective thermal dysregulation. Management is largely supportive: external warming for hypothermia and light clothing for hyperthermia. Hydrocortisone stress dosing should be considered when temperatures fall below 35.5 °C or exceed 38 °C.

Behavioral Problems

As the hypothalamus is tightly connected to limbic structures, hypothalamic dysfunction may cause diverse neurobehavioral abnormalities. Anxiety disorders are common, potentially due to perturbations of the Papez circuit (44), and memory impairments may also occur (18, 45). Lesions involving the nucleus accumbens have been associated with addictive behaviors, obsessive tendencies, hoarding, and compulsive eating (18). Combined with disrupted satiety signaling, these alterations contribute to severe obesity (20, 46). Cognitive dysfunction may also be present (47).

Neurocognitive Outcome

Studies of childhood CP survivors reveal wide variability in psychosocial and physical outcomes ranging from excellent functioning in most patients to significant impairment in nearly half (8, 48, 49, 50). Social and emotional functioning are frequently affected, with many patients rating psychosocial health lower than physical well-being (8). Challenges include learning difficulties, emotional dysregulation, peer relationship problems, and body-image concerns (51, 52). Worse outcomes are associated with preoperative impairment, younger age at CP diagnosis, hypothalamic involvement, larger tumors, and certain treatment strategies. Surgery alone yields poorer results than limited resection followed by radiotherapy; repeated surgeries also worsen long-term outcomes. Endocrine, neurological, and ophthalmological sequelae further diminish QoL (8, 48). Hypothalamic dysfunction exerts the greatest negative effect on social functioning, physical capacity, and body image (7, 8, 48).

Long-term survivors frequently experience cognitive deficits, particularly in episodic memory, executive functions, and attention (8, 51, 52). Ozyurt et al. (53) demonstrated that hypothalamic injury disrupted medial prefrontal cortex mechanisms during memory retrieval, indicating reduced executive control efficiency. Incomplete tumor resection followed by radiotherapy was associated with psychological and educational difficulties (52). Although most patients retain normal overall intelligence, visual memory is frequently impaired despite preserved visuospatial skills (51, 52). Early deficits in attention often predict poor academic performance.

Psychosocial Functioning

At a median follow-up age of 29 years, adults with CO CP reported similar psychosomatic and emotional well-being when compared to controls (54). Social interaction scores were comparable, though social integration appeared less adequate in patients. Educational attainment was slightly lower in the CP group, and employment rates were reduced (48% vs 62%), although unemployment benefits were similar. Notably, 14% of CP survivors, but none of the controls, were on long-term sick leave or disability pension. Dekkers et al. (55) reported reduced QoL in a mixed adult- and CO cohort with a mean follow-up of 20 years. Greater QoL impairment in adults may reflect a heightened sense of loss when diagnosis occurs later in life. In children, Müller et al. (49) found reduced QoL at 4.5 years post-diagnosis, particularly in those with hypothalamic involvement (Table 1).
Some studies suggest that outcomes improve over time due to psychological adaptation. However, CO CP survivors with hypothalamic damage consistently report reduced satisfaction with social participation and overall health, alongside lower educational and employment attainment, and constitute all cases receiving disability pension or long-term sick leave (54).

Despite extensive documentation of neurocognitive and psychosocial difficulties in CP survivors, targeted interventions remain scarce. Recent case studies have piloted cognitive rehabilitation for executive dysfunction and behavioral instability (56). One program combining goal-management therapy with structured workplace tasks yielded improvements in tasks requiring organization. Additional behavioral difficulties, including aggression, are common (8). In some individuals, behavioral analysis followed by reinforcement strategies and extinction techniques reduced aggressive episodes by >88% and increased adaptive behaviors (56). These observations indicate that structured rehabilitation may enable survivors of CO CP to develop compensatory strategies for neurocognitive and psychosocial deficits.

Quality of Life

Beckhaus et al. (57) analyzed the largest cohort reported to date (n=709) of individuals with CO CP, assessing clinical features at presentation and long-term outcomes including QoL. The study specifically examined whether age at diagnosis affected disease characteristics, therapeutic management, and prognosis. At final follow-up, severe obesity [BMI >3 standard deviation score (SDS)] was documented in 45.4% of patients. Posterior hypothalamic involvement and structural hypothalamic damage were identified as independent predictors of both reduced event-free survival and the presence of obesity at follow-up. Although overall survival did not vary by age at diagnosis, younger age (<12 years) was associated with an increased risk of disease progression and recurrence. Notably, children diagnosed before 6 years of age demonstrated lower event-free survival but reported higher QoL compared with those diagnosed at ≥6 years. Lower functional capacity percentiles were associated with higher BMI SDS at final assessment and with diagnosis before 2 years of age. These observations suggest that differences in management strategies such as the timing or modality of radiotherapy or intrinsic tumor biology may account for age-related outcome variability. Despite these disparities, overall survival remained comparable across age groups, implying that re-irradiation and surgical reintervention were effective in controlling tumor recurrence or progression. Functional capacity, reflecting performance in daily activities, differed substantially between age subgroups, with younger age at diagnosis predicting poorer long-term functional outcomes. Paradoxically, QoL scores based on both patient and parent reports were less favorable among those diagnosed at an older age, particularly regarding body image. Developmental factors may help explain this finding. In very young children, neurological and endocrine impairments heavily shape overall development. Conversely, older children and adolescents, whose brain maturation is more advanced, may experience fewer disruptions to developmental trajectories but are more capable of perceiving and evaluating changes in QoL compared with their pre-diagnosis baseline. Consequently, adolescents may be more sensitive to alterations in body image. Body shape and appearance constitute central determinants of QoL in adolescence.

Energy Balance

Energy homeostasis is maintained through the dynamic interaction between energy intake and energy expenditure, orchestrated by hypothalamic nuclei that integrate central and peripheral signals within complex neural circuits (21, 41). Energy intake is regulated by three principal processes: initiation of eating, cessation of eating, and food selection. The hypothalamus modulates these processes via orexigenic mediators such as orexin A/B, ghrelin, and neuropeptide Y and anorexigenic mediators, including adiponectin, leptin, brain-derived neurotrophic factor, and insulin. While gastrointestinal satiety signals contribute to terminating meals, food preference is influenced by the mesolimbic reward system and by prefrontal-amygdala networks that interact with hypothalamic centers. Energy expenditure consists of resting metabolic rate (60-75%), activity-related thermogenesis (~20%), and diet-induced thermogenesis (10-15%), all of which are modulated by sympathetic nervous system activity under hypothalamic regulation. Damage to the hypothalamus may disrupt parasympathetic control, leading to hyperinsulinemia and promoting adipose tissue deposition, thereby increasing the risk of obesity. The extent and nature of hypothalamic impairment depend on factors such as age at onset, tumor-related characteristics, and comorbidities, and may affect endocrine axes, neuroendocrine pathways, or inter-regional neural connections to varying degrees.

A key pathway in appetite control is the melanocortin system. Following food intake, leptin binds to its receptors on pro-opiomelanocortin neurons, stimulating the release of α- and β-melanocyte-stimulating hormones (α/β-MSH). These peptides activate melanocortin-4 receptors (MC4R), increasing satiety and energy expenditure. Disruption of this system contributes to hyperphagia and obesity (58). In addition, hypothalamic efferent pathways regulate sympathetic outflow, thereby influencing energy expenditure. Among 67 children with hypothalamic syndrome, 67.2% demonstrated a measured resting energy expenditure (mREE) below 90% of predicted REE (pREE) values, with the lowest mREE/pREE ratios observed in patients with severe or posterior hypothalamic injury, corresponding to higher rates of hypothalamic obesity (59). REE is also closely associated with muscle mass, which is metabolically more active than fat mass. Physical activity increases REE both directly, through muscle hypertrophy, and indirectly, via enhanced thermogenesis. In contrast, children with hypothalamic obesity typically exhibit reduced muscle mass due to low activity levels.

Physical Activity and Energy Expenditure

Accelerometry studies show that patients with CO CP engage in substantially less physical activity than BMI-matched controls (13). Reduced activity levels persist into adulthood (17). Patients report diminished participation in recreational physical activity year-round, and pedometer data corroborate lower daily step counts compared with healthy individuals. Severe hypothalamic obesity is commonly accompanied by EDS (60). CP survivors also exhibit reduced morning and nighttime salivary melatonin levels, which correlate with daytime somnolence and hypothalamic obesity. Melatonin supplementation (6 mg/day) can normalize melatonin profiles and transiently improve sleepiness and activity, though long-term benefit remains uncertain (61). Polysomnographic assessments in CP patients with pronounced hypothalamic obesity frequently reveal hypersomnia or secondary narcolepsy, including frequent sleep-onset REM periods. In such cases, central stimulants (e.g., methylphenidate, modafinil) significantly ameliorate daytime sleepiness and enhance activity (39).

Management strategies should emphasize increasing REE, for example through structured physical training, testosterone therapy to augment muscle mass, and active warming when hypothermia is present. Optimization of endocrine replacement (GH, thyroid hormone) is also essential. Pharmacological measures, such as dexamphetamine, may be appropriate in selected patients to further elevate energy expenditure (62, 63). Measurement of REE using ventilated-hood calorimetry offers clinically valuable insights into weight trajectories and informs individualized nutritional planning (59).

Hypothalamic Obesity and Disordered Eating

Under normal physiological conditions, satiety and body-weight regulation arise from a balanced interaction between anorexigenic and orexigenic signaling pathways. In hypothalamic obesity, this tightly coordinated network becomes impaired due to structural or functional disruption of key hypothalamic regions (58), resulting in dysregulated appetite control and inappropriate food intake (21). In patients with CP, increased parasympathetic activity mediated by heightened vagal tone contributes to hyperinsulinemia and persistent hunger, thereby promoting excessive weight gain (21). Concurrently, diminished sympathetic activity reduces total energy expenditure and lipolysis. Many individuals with hypothalamic obesity also exhibit reduced concentrations of α-MSH, a neuropeptide involved in driving energy expenditure.

A recently proposed consensus definition for acquired hypothalamic obesity (64) included the following diagnostic criteria:

- A traumatic event or oncologic disease resulting in hypothalamic damage detectable on magnetic resonance imaging;

- A rapid (within 12 months of surgery/diagnosis), persistent (for at least 24 months), and clinically significant increase in BMI (≥5% increase in adults; ≥1.0 SDS increase in children) beginning within 12 months after the onset of hypothalamic injury, with clinical and anthropometric monitoring at 3-month intervals;

- Development of obesity meeting defined thresholds (BMI SDS≥+2.0 SD in children; BMI≥25 kg/m2 or ≥30 kg/m2 in adults, with adjustment for racial and ethnic factors).

Long-term follow-up showed that approximately half of CO CP patients with hypothalamic lesions developed hypothalamic obesity (7, 65). In a study by Rovani et al. (66), 54% of CP survivors were overweight or obese, with risk factors including female sex, hypothalamic involvement, and baseline BMI>+2 SDS. Beckhaus et al. (67) further demonstrated that familial susceptibility, reflected by elevated maternal and paternal BMI at the patient’s time of diagnosis, was strongly associated with the development of severe hypothalamic obesity. In a mixed AO/CO cohort, the prevalence of excessive weight gain or hyperphagia increased from 39% at 10 years to 67% at 20 years post-diagnosis. Once severe obesity is established, weight reduction becomes extremely difficult (21) and many patients reach a high but stable BMI plateau (27). Currently, no uniformly effective therapy exists (58). Therapeutic efforts therefore focus on preventing hypothalamic injury through hypothalamus-sparing surgical techniques, precision radiation modalities (e.g., proton beam therapy), and emerging pharmacologic treatments specifically targeting hypothalamic obesity (5). In pCP harboring the BRAF V600E mutation, targeted therapy with BRAF inhibitors has also demonstrated encouraging results (68).

Hyperphagia

Hyperphagia in children with hypothalamic obesity may be profound, sometimes necessitating strict household controls to prevent food seeking and food theft. However, hyperphagia is not universally present in all affected individuals (43). When designing dietary interventions, it is important to recognize that hypothalamic dysfunction is typically lifelong rather than transient. A systematic review evaluating lifestyle and dietary interventions for hypothalamic obesity included 12 studies involving 118 patients with CP, monogenic obesity, PWS, or rapid-onset obesity with hypothalamic dysfunction, hypoventilation and autonomic dysregulation syndrome. Four studies concluded that dietary interventions were feasible but reported multiple challenges. Among the seven studies assessing efficacy, both balanced hypocaloric diets (30% fat, 45% carbohydrates, 25% protein) and more stringent regimens (8-10 kcal/cm/day) were associated with stabilization or reduction of body weight (69).

Hypophagia

Although less common, hypophagia can also occur in individuals with hypothalamic dysfunction. In CO CP, anorexia or reduced intake is unusual but has been documented, especially in younger children. The German KRANIOPHARYNGEOM cohort reported that 11 of 485 patients initially presented with anorexia (14). In infants with PWS, atypical eating behavior has been linked to altered ghrelin acylation patterns. Management is primarily dietary. But given the potential transition from hypophagia to hyperphagia over time, continuous monitoring and timely intervention are crucial.

Treatment of Hypothalamic Obesity

Lifestyle Interventions

Lifestyle approaches have typically produced only short-term reductions in BMI, indicating that sustained weight control requires long-term, structured behavioral support (Table 2). A stable and supportive home environment is essential, particularly given the persistent combination of hyperphagia, pituitary hormonal deficits, and behavioral challenges (70). Data from the German KRANIOPHARYNGEOM cohort (n=291) showed that BMI at final follow-up strongly correlated with maternal and paternal BMI at diagnosis (67) underscoring the need for family-centered obesity management. Engaging caregivers and family members is therefore critical to achieving durable therapeutic outcomes.

Antidiabetic Medications

Multiple antidiabetic agents such as glucagon-like peptide-1 (GLP-1) receptor agonists, metformin, diazoxide, fenofibrate, pioglitazone, and various combination regimens (71) have demonstrated potential benefits in limiting weight gain and enhancing insulin sensitivity in individuals with hypothalamic obesity. Among these, metformin appears particularly advantageous when used alongside lifestyle modification, as it offers moderate weight stabilization with a generally favorable safety profile (72). Nevertheless, the long-term efficacy and safety of metformin specifically for hypothalamic obesity have not yet been fully characterized (73).

GLP-1 receptor agonists

A small study including 26 adults with hypothalamic obesity reported that all but one patient achieved weight reduction during semaglutide therapy, with an average weight loss of 13.4 kg and a corresponding BMI decrease of 4.4 kg/m2 after one year (74). Consistent with these findings, a systematic review of 10 studies concluded that GLP-1 receptor agonists may represent a safe and effective intervention for weight management in this population (75). Despite encouraging results, the therapeutic effect of GLP-1 receptor agonists in adults with hypothalamic obesity remains under discussion. Several investigations have documented improved glycemic control and reductions in food intake (75, 76), yet Shoemaker et al. (76) observed an unexpected decline in total energy expenditure following weekly exenatide administration, out of proportion to weight loss and unrelated to physical activity or leptin levels. Conversely, Perez et al. (77) reported that individuals with more extensive hypothalamic injury experienced greater adiposity reductions under the same exenatide dose. The GLP-1 analogue liraglutide, approved for long-term management of general obesity, has been used in adults with CP-related hypothalamic obesity, leading to weight reductions of 9-22 kg (78). Semaglutide is similarly approved for obesity treatment in adolescents, achieving a median BMI reduction of approximately 17%. Early evidence suggests that semaglutide and exenatide may hold therapeutic value for weight control in hypothalamic obesity (79).

Setmelanotide

Setmelanotide, a MC4R agonist, has shown marked effectiveness in children with monogenic obesity syndromes such as Bardet-Biedl syndrome. Originally developed for congenital hypothalamic obesity caused by proopiomelanocortin or leptin receptor deficiency (80), setmelanotide activates remaining MC4R-expressing neurons within the hypothalamus. Impairment of this pathway leads to profound hyperphagia and subsequent hypothalamic obesity. In a phase 2 study including pediatric and adult participants with acquired hypothalamic obesity, setmelanotide resulted in a mean BMI decrease of 15±10%, together with notable improvements in hyperphagic symptoms and QoL (81).

Preliminary data from a prospective, placebo-controlled clinical trial (NCT05774756) involving 120 affected individuals revealed that 52-week treatment produced a mean BMI reduction of 16.5% in the setmelanotide group (n=81), compared with a 3.3% BMI increase in the placebo cohort (n=39). Furthermore, 80% of treated patients achieved at least a 5% BMI reduction at 52 weeks (82). Collectively, these findings indicate that setmelanotide might represent a promising pharmacologic therapy for hypothalamic obesity (83) (Table 2).

Combination of oral phentermine and topiramate (Ph/T)

Phentermine is a sympathomimetic amine, while topiramate is a GABAergic agent commonly used as an anticonvulsant. Given that patients with hypothalamic obesity frequently exhibit diminished sympathetic nervous system activity (84), they may theoretically benefit from the appetite-suppressing effects of central stimulants (85, 86). The combination of oral phentermine and topiramate (Ph/T) is approved by the U.S. Food and Drug Administration for use in individuals aged 12 years and older with obesity (87). Nevertheless, the efficacy and safety of Ph/T have not yet been systematically investigated in patients with confirmed hypothalamic obesity.

Tesofensine

Tesofensine is a centrally acting triple monoamine reuptake inhibitor that may counter the reduced sympathetic tone commonly observed in hypothalamic obesity. By blocking presynaptic reuptake of dopamine, serotonin, and noradrenaline and inhibiting the dopamine active transporter, tesofensine reduces caloric intake and promotes weight loss. To attenuate potential adrenergic adverse effects, it is administered in combination with the beta-blocker metoprolol. A randomized, double-blind, placebo-controlled phase 2 trial involving 21 individuals assessed Tesomet (tesofensine plus metoprolol) for hypothalamic obesity (88). Patients in the treatment arm exhibited reductions in body weight, waist circumference, and blood glucose relative to placebo.

Somatostatin and the autonomic nervous system

Lustig et al. (89) proposed that patients with CO CP may experience a loss of hypothalamic inhibitory control, resulting in increased vagal output and overstimulation of pancreatic β-cells. This leads to hyperinsulinemia and contributes to severe obesity. Based on this model, they tested the somatostatin analogue octreotide, which suppresses β-cell activity (89). However, its clinical utility has been limited by modest efficacy and frequent adverse effects, including gastrointestinal symptoms and gallstone formation. Other studies have implicated reduced sympathetic activity in decreased physical activity and pronounced obesity. Supporting this, Roth et al. (84) reported lower urinary catecholamine metabolite levels, correlating with both severity of obesity and reduced activity.

Central stimulating agents

A range of central nervous system stimulants, including methylphenidate, phentermine, dextroamphetamine, mazindol, caffeine, and ephedrine, has been used off-label in hypothalamic obesity (62, 63, 85). Two small pediatric case series documented that dexamphetamine therapy resulted in reductions in BMI, increased REE, and improved energy levels among affected children (62).

Oxytocin treatment

Oxytocin, a neuropeptide playing a central role for social behavior and reproduction, also influences appetite regulation and satiety. It has been shown to reduce food intake and suppress hunger. In CP patients, altered salivary oxytocin responses to food and exercise have been associated with differences in BMI and disordered eating behaviors (90). These findings suggest potential therapeutic utility for oxytocin in hypothalamic obesity. However, the mechanisms underlying its metabolic effects in the setting of hypothalamic injury remain poorly defined, and optimal dosing, delivery approaches, and long-term safety require further investigation.

Bariatric Interventions

Bariatric surgery has demonstrated meaningful weight-loss efficacy and safety in individuals with CP (Table 1). In an individual-level meta-analysis of 21 cases, Bretault et al. (91) reported total weight loss of -0.9% at 6 months and -15.1% at 12 months post-operatively, with the greatest reductions observed after Roux-en-Y gastric bypass (RYGB). In children and adolescents, irreversible bariatric procedures such as RYGB remain ethically and legally challenging, and their use is generally restricted to clinical trial settings (92). The Endocrine Society’s Clinical Practice Guideline (93) recommends considering bariatric surgery only for adolescents with morbid obesity, who have reached advanced pubertal maturation and near final or final adult height, and who have demonstrated adherence to lifestyle interventions.

Prevention of Hypothalamic Dysfunction through Hypothalamus-Sparing Approaches

Eveslage et al. (94) demonstrated that preoperative hypothalamic involvement and intraoperative damage to anterior and posterior hypothalamic nuclei are associated with reduced QoL and increased BMI in CP survivors. Complete surgical resection was linked to worse BMI and QoL outcomes compared with subtotal surgery (94) (Figure 2). Lesions confined to the anterior hypothalamus tended to produce fewer adverse effects, whereas injury to posterior regions markedly increased the risk of hypothalamic syndrome and impaired QoL (95). Consequently, surgical strategies should emphasize preservation of posterior hypothalamic structures. These hypothalamus-sparing techniques may increase the likelihood of tumor recurrence or progression. Radiotherapy therefore plays a pivotal role in managing residual disease and preventing relapse, forming a central component of hypothalamus-preserving treatment paradigms for CP (2, 96).

Conclusion

Hypothalamic syndrome substantially affects morbidity and QoL in patients with CP, and current therapeutic outcomes remain unsatisfactory. The heterogeneity of hypothalamic syndrome indicates that a standardized treatment approach is unlikely to be effective. Accordingly, personalized management algorithms have been proposed to improve care (20, 21). Treatment decisions that prioritize the preservation of hypothalamic, neuroendocrine, and visual function should be made within experienced multidisciplinary teams. Establishing multicenter reference networks is essential to ensure standardized, high-quality care and access to specialized expertise (97). Future strategies to improve outcomes should include deeper investigation into the molecular pathogenesis of CP, facilitating the development of targeted therapies that address tumor progression and hypothalamic involvement. Advances in surgery and radiotherapy should focus on hypothalamus-sparing approaches to limit long-term neuroendocrine and metabolic consequences (98). In addition, policy-level initiatives are needed to define and implement quality standards for comprehensive multidisciplinary management of CP.

Competing Interests: HLM has received reimbursement of participation fees for scientific meetings and continuing medical education events, and reimbursement of travel expenses and lecture honoraria from Rhythm Pharmaceuticals.
Conflict of interest: None declared.
Financial Disclosure: HLM and the KRANIOPHARYNGEOM studies have been funded by grants (H.L.M., DKS2014.13) of the German Childhood Cancer Foundation, Bonn, Germany.

References

1
Müller HL. Management of Acquired Hypothalamic Obesity After Childhood-Onset Craniopharyngioma-A Narrative Review. Biomedicines. 2025;13:1016.
2
Müller HL. Craniopharyngioma. Endocr Rev. 2014;35:513-543. Epub 2014 Jan 27
3
Witte J, Surmann B, Batram M, Weinert M, Flume M, Touchot N, Beckhaus J, Friedrich C, Müller HL. Hypothalamic obesity: Epidemiology in rare sellar/suprasellar tumors-A German claims database analysis. J Neuroendocrinol. 2024;36:e13439. Epub 2024 Aug 27
4
Santagata S, Kleinschmidt-DeMasters BK, Komori T, Müller HL, Pietsch T. Adamantinomatous craniopharyngioma. In: Brat DJ GA, Wesseling P (eds) Tumours of the sellar region), editor. WHO Classification of Tumours Editorial Board Central nervous system tumours. WHO classification of tumours series. 6. 5th ed. Lyon (France), International Agency for Research on Cancer, 2021;393-396.
5
Apps JR, Muller HL, Hankinson TC, Yock TI, Martinez-Barbera JP. Contemporary Biological Insights and Clinical Management of Craniopharyngioma. Endocr Rev. 2023;44:518-538.
6
Pereira AM, Schmid EM, Schutte PJ, Voormolen JH, Biermasz NR, van Thiel SW, Corssmit EP, Smit JW, Roelfsema F, Romijn JA. High prevalence of long-term cardiovascular, neurological and psychosocial morbidity after treatment for craniopharyngioma. Clin Endocrinol (Oxf). 2005;62:197-204.
7
Müller HL, Bueb K, Bartels U, Roth C, Harz K, Graf N, Korinthenberg R, Bettendorf M, Kühl J, Gutjahr P, Sörensen N, Calaminus G. Obesity after childhood craniopharyngioma--German multicenter study on pre-operative risk factors and quality of life. Klin Padiatr. 2001;213:244-249.
8
Poretti A, Grotzer MA, Ribi K, Schönle E, Boltshauser E. Outcome of craniopharyngioma in children: long-term complications and quality of life. Dev Med Child Neurol. 2004;46:220-229.
9
Hoffmann A, Bootsveld K, Gebhardt U, Daubenbüchel AM, Sterkenburg AS, Müller HL. Nonalcoholic fatty liver disease and fatigue in long-term survivors of childhood-onset craniopharyngioma. Eur J Endocrinol. 2015;173:389-397. Epub 2015 Jun 18
10
Erfurth EM, Holmer H, Fjalldal SB. Mortality and morbidity in adult craniopharyngioma. Pituitary. 2013;16:46-55.
11
Daubenbüchel AM, Hoffmann A, Gebhardt U, Warmuth-Metz M, Sterkenburg AS, Müller HL. Hydrocephalus and hypothalamic involvement in pediatric patients with craniopharyngioma or cysts of Rathke’s pouch: impact on long-term prognosis. Eur J Endocrinol. 2015;172:561-569. Epub 2015 Feb 3
12
Sterkenburg AS, Hoffmann A, Gebhardt U, Warmuth-Metz M, Daubenbüchel AM, Müller HL. Survival, hypothalamic obesity, and neuropsychological/psychosocial status after childhood-onset craniopharyngioma: newly reported long-term outcomes. Neuro Oncol. 2015;17:1029-1038. Epub 2015 Apr 2
13
Harz KJ, Müller HL, Waldeck E, Pudel V, Roth C. Obesity in patients with craniopharyngioma: assessment of food intake and movement counts indicating physical activity. J Clin Endocrinol Metab. 2003;88:5227-5231.
14
Hoffmann A, Gebhardt U, Sterkenburg AS, Warmuth-Metz M, Müller HL. Diencephalic syndrome in childhood craniopharyngioma--results of German multicenter studies on 485 long-term survivors of childhood craniopharyngioma. J Clin Endocrinol Metab. 2014;99:3972-3977. Epub 2014 Jul 31
15
Mann-Markutzyk LV, Beckhaus J, Özyurt J, Mehren A, Friedrich C, Müller HL. Daytime sleepiness and health-related quality of life in patients with childhood-onset craniopharyngioma. Sci Rep. 2025;15:9407.
16
Müller HL. Increased daytime sleepiness in patients with childhood craniopharyngioma and hypothalamic tumor involvement: review of the literature and perspectives. Int J Endocrinol. 2010;2010:519607. Epub 2010 Dec 16
17
Holmer H, Pozarek G, Wirfält E, Popovic V, Ekman B, Björk J, Erfurth EM. Reduced energy expenditure and impaired feeding-related signals but not high energy intake reinforces hypothalamic obesity in adults with childhood onset craniopharyngioma. J Clin Endocrinol Metab. 2010;95:5395-5402. Epub 2010 Sep 8
18
Özyurt J, Thiel CM, Lorenzen A, Gebhardt U, Calaminus G, Warmuth-Metz M, Müller HL. Neuropsychological outcome in patients with childhood craniopharyngioma and hypothalamic involvement. J Pediatr. 2014;164:876-881. Epub 2014 Feb 6
19
Witte J, Touchot N, Batram M, Diekmannshemke J, Flume M, Müller HL. Epidemiology of acquired hypothalamic obesity following traumatic brain injury and nonspecific hypothalamic microinjury: A nationwide German claims data analysis. J Neuroendocrinol. 2025:e70108. Epub 2025 Nov 14
20
van Santen HM, van Schaik J, van Roessel IMAA, Beckhaus J, Boekhoff S, Müller HL. Diagnostic criteria for the hypothalamic syndrome in childhood. Eur J Endocrinol. 2023;188:Iva009.
21
van Iersel L, Brokke KE, Adan RAH, Bulthuis LCM, van den Akker ELT, van Santen HM. Pathophysiology and Individualized Treatment of Hypothalamic Obesity Following Craniopharyngioma and Other Suprasellar Tumors: A Systematic Review. Endocr Rev. 2019;40:193-235.
22
van Santen HM, Müller HL. Management of Acquired Hypothalamic Dysfunction and the Hypothalamic Syndrome; It Is More Than Obesity. Endocr Rev. 2025;46:891-907.
23
Doelman-Oldenburger NJ, Müller HL, van Santen HM. Novel autonomic dysregulation score in children with hypothalamic syndrome. Endocr Connect. 2025;14:e250336.
24
Müller HL, Gebhardt U, Teske C, Faldum A, Zwiener I, Warmuth-Metz M, Pietsch T, Pohl F, Sörensen N, Calaminus G; Study Committee of KRANIOPHARYNGEOM 2000. Post-operative hypothalamic lesions and obesity in childhood craniopharyngioma: results of the multinational prospective trial KRANIOPHARYNGEOM 2000 after 3-year follow-up. Eur J Endocrinol. 2011;165:17-24. Epub 2011 Apr 13
25
Müller HL, Gebhardt U, Faldum A, Warmuth-Metz M, Pietsch T, Pohl F, Calaminus G, Sörensen N; Kraniopharyngeom 2000 Study Committee. Xanthogranuloma, Rathke’s cyst, and childhood craniopharyngioma: results of prospective multinational studies of children and adolescents with rare sellar malformations. J Clin Endocrinol Metab. 2012;97:3935-3943. Epub 2012 Sep 11
26
Van Schaik J, Schouten-van Meeteren AYN, Vos-Kerkhof E, Janssens GO, Porro GL, Fiocco M, Bakker B, Tissing WJE, Hoving EW, van Santen HM. Treatment and outcome of the Dutch Childhood Craniopharyngioma Cohort study: First results after centralization of care. Neuro Oncol. 2023;25:2250-2261.
27
Sterkenburg AS, Hoffmann A, Gebhardt U, Warmuth-Metz M, Daubenbüchel AM, Müller HL. Survival, hypothalamic obesity, and neuropsychological/psychosocial status after childhood-onset craniopharyngioma: newly reported long-term outcomes. Neuro Oncol. 2015;17:1029-1038. Epub 2015 Apr 2
28
Boguszewski MCS, Boguszewski CL, Chemaitilly W, Cohen LE, Gebauer J, Higham C, Hoffman AR, Polak M, Yuen KCJ, Alos N, Antal Z, Bidlingmaier M, Biller BMK, Brabant G, Choong CSY, Cianfarani S, Clayton PE, Coutant R, Cardoso-Demartini AA, Fernandez A, Grimberg A, Guðmundsson K, Guevara-Aguirre J, Ho KKY, Horikawa R, Isidori AM, Jørgensen JOL, Kamenicky P, Karavitaki N, Kopchick JJ, Lodish M, Luo X, McCormack AI, Meacham L, Melmed S, Mostoufi Moab S, Müller HL, Neggers SJCMM, Aguiar Oliveira MH, Ozono K, Pennisi PA, Popovic V, Radovick S, Savendahl L, Touraine P, van Santen HM, Johannsson G. Safety of growth hormone replacement in survivors of cancer and intracranial and pituitary tumours: a consensus statement. Eur J Endocrinol. 2022;186:P35-P52.
29
Heinks K, Boekhoff S, Hoffmann A, Warmuth-Metz M, Eveslage M, Peng J, Calaminus G, Müller HL. Quality of life and growth after childhood craniopharyngioma: results of the multinational trial KRANIOPHARYNGEOM 2007. Endocrine. 2018;59:364-372. Epub 2017 Dec 11
30
Müller HL, Heinrich M, Bueb K, Etavard-Gorris N, Gebhardt U, Kolb R, Sörensen N. Perioperative dexamethasone treatment in childhood craniopharyngioma--influence on short-term and long-term weight gain. Exp Clin Endocrinol Diabetes. 2003;111:330-334.
31
van Iersel L, Xu J, Potter BS, Conklin HM, Zhang H, Chemaitilly W, van Santen HM, Merchant TE. Clinical Importance of Free Thyroxine Concentration Decline After Radiotherapy for Pediatric and Adolescent Brain Tumors. J Clin Endocrinol Metab. 2019;104:4998-5007.
32
Sowithayasakul P, Boekhoff S, Bison B, Müller HL. Pregnancies after Childhood Craniopharyngioma: Results of KRANIOPHARYNGEOM 2000/2007 and Review of the Literature. Neuroendocrinology. 2021;111:16-26. Epub 2020 Feb 20
33
Daubenbüchel AM, Özyurt J, Boekhoff S, Warmuth-Metz M, Eveslage M, Müller HL. Eating behaviour and oxytocin in patients with childhood-onset craniopharyngioma and different grades of hypothalamic involvement. Pediatr Obes. 2019;14:e12527. Epub 2019 Apr 23
34
Daubenbüchel AM, Hoffmann A, Eveslage M, Özyurt J, Lohle K, Reichel J, Thiel CM, Martens H, Geenen V, Müller HL. Oxytocin in survivors of childhood-onset craniopharyngioma. Endocrine. 2016;54:524-531. Epub 2016 Sep 1
35
Hoffmann A, Özyurt J, Lohle K, Reichel J, Thiel CM, Müller HL. First experiences with neuropsychological effects of oxytocin administration in childhood-onset craniopharyngioma. Endocrine. 2017;56:175-185. Epub 2017 Feb 17
36
Özyurt J, Mehren A, Boekhoff S, Müller HL, Thiel CM. Social Cognition in Patients With Hypothalamic-Pituitary Tumors. Front Oncol. 2020;10:1014.
37
Müller HL. Management of Hypothalamic Obesity. Endocrinol Metab Clin North Am. 2020;49:533-552. Epub 2020 Jul 15
38
Lin B, Xiang S, Chen J, Jing Y, Ye Z, Zhang Y, Cao X, Yin Z, Qiao N, Zhou X. Assessment of quality of life in patients with craniopharyngioma and identification of risk factors for compromised overall wellness. Arch Endocrinol Metab. 2023;68:e230001.
39
Müller HL, Müller-Stöver S, Gebhardt U, Kolb R, Sörensen N, Handwerker G. Secondary narcolepsy may be a causative factor of increased daytime sleepiness in obese childhood craniopharyngioma patients. J Pediatr Endocrinol Metab. 2006;19(Suppl 1):423-429.
40
Romigi A, Feola T, Cappellano S, De Angelis M, Pio G, Caccamo M, Testa F, Vitrani G, Centonze D, Colonnese C, Esposito V, Jaffrain-Rea ML. Sleep Disorders in Patients With Craniopharyngioma: A Physiopathological and Practical Update. Front Neurol. 2021;12:817257.
41
Tran LT, Park S, Kim SK, Lee JS, Kim KW, Kwon O. Hypothalamic control of energy expenditure and thermogenesis. Exp Mol Med. 2022;54:358-369. Epub 2022 Mar 17
42
Müller HL, Tauber M, Lawson EA, Özyurt J, Bison B, Martinez-Barbera JP, Puget S, Merchant TE, van Santen HM. Hypothalamic syndrome. Nat Rev Dis Primers. 2022;8:24.
43
van Roessel IMAA, Hulsmann SC, Schouten-van Meeteren AYN, Hoving EW, Janssens GO, Raphael MF, Zijtregtop-Blom EAM, de Vos-Kerkhof E, Bakker B, Tissing WJE, van Santen HM. The many different clinical faces of acquired hypothalamic dysfunction: a retrospective cohort study in the Netherlands. EClinicalMedicine. 2025;85:103313.
44
Mehren A, Özyurt J, Zu Klampen P, Boekhoff S, Thiel CM, Müller HL. Self- and informant-rated apathy in patients with childhood-onset craniopharyngioma. J Neurooncol. 2018;140:27-35. Epub 2018 Jul 3
45
Özyurt J, Müller HL, Thiel CM. A systematic review of cognitive performance in patients with childhood craniopharyngioma. J Neurooncol. 2015;125:9-21. Epub 2015 Sep
46
Müller HL, Emser A, Faldum A, Bruhnken G, Etavard-Gorris N, Gebhardt U, Oeverink R, Kolb R, Sörensen N. Longitudinal study on growth and body mass index before and after diagnosis of childhood craniopharyngioma. J Clin Endocrinol Metab. 2004;89:3298-3305.
47
Fjalldal S, Holmer H, Rylander L, Elfving M, Ekman B, Osterberg K, Erfurth EM. Hypothalamic involvement predicts cognitive performance and psychosocial health in long-term survivors of childhood craniopharyngioma. J Clin Endocrinol Metab. 2013;98:3253-3262. Epub 2013 Jun 14
48
Müller HL, Faldum A, Etavard-Gorris N, Gebhardt U, Oeverink R, Kolb R, Sörensen N. Functional capacity, obesity and hypothalamic involvement: cross-sectional study on 212 patients with childhood craniopharyngioma. Klin Padiatr. 2003;215:310-314.
49
Müller HL, Bruhnken G, Emser A, Faldum A, Etavard-Gorris N, Gebhardt U, Kolb R, Sörensen N. Longitudinal study on quality of life in 102 survivors of childhood craniopharyngioma. Childs Nerv Syst. 2005;21:975-980. Epub 2005 Jun 18
50
Müller HL, Gebhardt U, Faldum A, Emser A, Etavard-Gorris N, Kolb R, Sörensen N. Functional capacity and body mass index in patients with sellar masses--cross-sectional study on 403 patients diagnosed during childhood and adolescence. Childs Nerv Syst. 2005;21:539-545. Epub 2005 May 12
51
Ondruch A, Maryniak A, Kropiwnicki T, Roszkowski M, Daszkiewicz P. Cognitive and social functioning in children and adolescents after the removal of craniopharyngioma. Childs Nerv Syst. 2011;27:391-397. Epub 2010 Oct 8
52
Crom DB, Smith D, Xiong Z, Onar A, Hudson MM, Merchant TE, Morris EB. Health status in long-term survivors of pediatric craniopharyngiomas. J Neurosci Nurs. 2010;42:329-330.
53
Ozyurt J, Lorenzen A, Gebhardt U, Warmuth-Metz M, Müller HL, Thiel CM. Remote effects of hypothalamic lesions in the prefrontal cortex of craniopharygioma patients. Neurobiol Learn Mem. 2014;111:71-80. Epub 2014 Mar 22
54
Fjalldal S, Follin C, Svärd D, Rylander L, Gabery S, Petersén Å, van Westen D, Sundgren PC, Björkman-Burtscher IM, Lätt J, Ekman B, Johanson A, Erfurth EM. Microstructural white matter alterations and hippocampal volumes are associated with cognitive deficits in craniopharyngioma. Eur J Endocrinol. 2018;178:577-587. Epub 2018 Mar 29
55
Dekkers OM, Biermasz NR, Smit JW, Groot LE, Roelfsema F, Romijn JA, Pereira AM. Quality of life in treated adult craniopharyngioma patients. Eur J Endocrinol. 2006;154:483-489.
56
Hammond JL, Hall SS. Functional analysis and treatment of aggressive behavior following resection of a craniopharyngioma. Dev Med Child Neurol. 2011;53:369-374. Epub 2011 Jan 14
57
Beckhaus J, Friedrich C, Boekhoff S, Calaminus G, Bison B, Eveslage M, Timmermann B, Flitsch J, Müller HL. Outcome after pediatric craniopharyngioma: the role of age at diagnosis and hypothalamic damage. Eur J Endocrinol. 2023;188:Ivad027.
58
Gan HW, Cerbone M, Dattani MT. Appetite- and Weight-Regulating Neuroendocrine Circuitry in Hypothalamic Obesity. Endocr Rev. 2024;45:309-342.
59
Van Schaik J, Burghard M, Lequin MH, van Maren EA, van Dijk AM, Takken T, Rehorst-Kleinlugtenbelt LB, Bakker B, Meijer L, Hoving EW, Fiocco M, Schouten-van Meeteren AYN, Tissing WJE, van Santen HM. Resting energy expenditure in children at risk of hypothalamic dysfunction. Endocr Connect. 2022;11:e220276.
60
Müller HL, Handwerker G, Gebhardt U, Faldum A, Emser A, Kolb R, Sörensen N. Melatonin treatment in obese patients with childhood craniopharyngioma and increased daytime sleepiness. Cancer Causes Control. 2006;17:583-589.
61
Müller HL, Handwerker G, Wollny B, Faldum A, Sörensen N. Melatonin secretion and increased daytime sleepiness in childhood craniopharyngioma patients. J Clin Endocrinol Metab. 2002;87:3993-3996.
62
Denzer C, Denzer F, Lennerz BS, Vollbach H, Lustig RH, Wabitsch M. Treatment of Hypothalamic Obesity with Dextroamphetamine: A Case Series. Obes Facts. 2019;12:91-102. Epub 2019 Mar 7
63
van Schaik J, Welling MS, de Groot CJ, van Eck JP, Juriaans A, Burghard M, Oude Ophuis SBJ, Bakker B, Tissing WJE, Schouten-van Meeteren AYN, van den Akker ELT, van Santen HM. Dextroamphetamine Treatment in Children With Hypothalamic Obesity. Front Endocrinol (Lausanne). 2022;13:845937.
64
Müller HL, Tanaka T, Hasegawa T, Isojima T, Mori J, Kurosaki M, Nishioka H, Choi HJ, Hong AR, Kim JH, Arima H. Diagnostic criteria for acquired hypothalamic obesity - international expert guidance document. Endocr J. 2026;73:341-353. Epub 2025 Nov 11
65
Hoffmann A, Postma FP, Sterkenburg AS, Gebhardt U, Müller HL. Eating behavior, weight problems and eating disorders in 101 long-term survivors of childhood-onset craniopharyngioma. J Pediatr Endocrinol Metab. 2015;28:35-43.
66
Rovani S, Butler V, Samara-Boustani D, Pinto G, Gonzalez-Briceno L, Nguyen Quoc A, Vermillac G, Stoupa A, Besançon A, Beltrand J, Thalassinos C, Flechtner I, Dassa Y, Viaud M, Arrom-Branas MB, Boddaert N, Puget S, Blauwblomme T, Alapetite C, Bolle S, Doz F, Grill J, Dufour C, Bourdeaut F, Abbou S, Guerrini-Rousseau L, Leruste A, Beccaria K, Polak M, Kariyawasam D. Long-term weight gain in children with craniopharyngioma. Eur J Endocrinol. 2024;190:363-373.
67
Beckhaus J, Eveslage M, Bison B, Friedrich C, Müller HL. Impact of parental body mass index at diagnosis on obesity in survivors of pediatric craniopharyngioma. Endocr Connect. 2024;13:e240126.
68
Brastianos PK, Twohy E, Geyer S, Gerstner ER, Kaufmann TJ, Tabrizi S, Kabat B, Thierauf J, Ruff MW, Bota DA, Reardon DA, Cohen AL, De La Fuente MI, Lesser GJ, Campian J, Agarwalla PK, Kumthekar P, Mann B, Vora S, Knopp M, Iafrate AJ, Curry WT Jr, Cahill DP, Shih HA, Brown PD, Santagata S, Barker FG 2nd, Galanis E. BRAF-MEK Inhibition in Newly Diagnosed Papillary Craniopharyngiomas. N Engl J Med. 2023;389:118-126.
69
Van Roessel IMAA, Van Den Brink M, Dekker J, Ruitenburg-van Essen BG, Tissing WJE, van Santen HM. Feasibility, safety, and efficacy of dietary or lifestyle interventions for hypothalamic obesity: A systematic review. Clin Nutr. 2024;43:1798-1811. Epub 2024 May 27
70
Meijneke RW, Schouten-van Meeteren AY, de Boer NY, van Zundert S, van Trotsenburg PA, Stoelinga F, van Santen HM. Hypothalamic obesity after treatment for craniopharyngioma: the importance of the home environment. J Pediatr Endocrinol Metab. 2015;28:59-63.
71
Hamilton JK, Conwell LS, Syme C, Ahmet A, Jeffery A, Daneman D. Hypothalamic Obesity following Craniopharyngioma Surgery: Results of a Pilot Trial of Combined Diazoxide and Metformin Therapy. Int J Pediatr Endocrinol. 2011;2011:417949. Epub 2011 Mar 22
72
Kalina MA, Wilczek M, Kalina-Faska B, Skała-Zamorowska E, Mandera M, Małecka Tendera E. Carbohydrate-lipid profile and use of metformin with micronized fenofibrate in reducing metabolic consequences of craniopharyngioma treatment in children: single institution experience. J Pediatr Endocrinol Metab. 2015;28:45-51.
73
Masarwa R, Brunetti VC, Aloe S, Henderson M, Platt RW, Filion KB. Efficacy and Safety of Metformin for Obesity: A Systematic Review. Pediatrics. 2021;147:e20201610.
74
Svendstrup M, Rasmussen AK, Kistorp C, Klose M, Andreassen M. Semaglutide treatment of hypothalamic obesity - a real-life data study. Pituitary. 2024;27:685-692. Epub 2024 Aug 9
75
Ng VWW, Gerard G, Koh JJK, Loke KY, Lee YS, Ng NBH. The role of glucagon-like peptide 1 receptor agonists for weight control in individuals with acquired hypothalamic obesity-A systematic review. Clin Obes. 2024;14:e12642. Epub 2024 Jan 25
76
Shoemaker AH, Silver HJ, Buchowski M, Slaughter JC, Yanovski JA, Elfers C, Roth CL, Abuzzahab MJ. Energy balance in hypothalamic obesity in response to treatment with a once-weekly GLP-1 receptor agonist. Int J Obes (Lond). 2022;46:623-629. Epub 2022 Jan 3
77
Perez FA, Elfers C, Yanovski JA, Shoemaker AH, Abuzzahab MJ, Roth CL. MRI measures of hypothalamic injury are associated with glucagon-like peptide-1 receptor agonist treatment response in people with hypothalamic obesity. Diabetes Obes Metab. 2021;23:1532-1541. Epub 2021 Mar 29
78
Zoicas F, Droste M, Mayr B, Buchfelder M, Schöfl C. GLP-1 analogues as a new treatment option for hypothalamic obesity in adults: report of nine cases. Eur J Endocrinol. 2013;168:699-706.
79
Roth CL, Perez FA, Whitlock KB, Elfers C, Yanovski JA, Shoemaker AH, Abuzzahab MJ. A phase 3 randomized clinical trial using a once-weekly glucagon-like peptide-1 receptor agonist in adolescents and young adults with hypothalamic obesity. Diabetes Obes Metab. 2021;23:363-373. Epub 2020 Oct 25
80
Wabitsch M, Farooqi S, Flück CE, Bratina N, Mallya UG, Stewart M, Garrison J, van den Akker E, Kühnen P. Natural History of Obesity Due to POMC, PCSK1, and LEPR Deficiency and the Impact of Setmelanotide. J Endocr Soc. 2022;6:bvac057.
81
Roth CL, Scimia C, Shoemaker AH, Gottschalk M, Miller J, Yuan G, Malhotra S, Abuzzahab MJ. Setmelanotide for the treatment of acquired hypothalamic obesity: a phase 2, open-label, multicentre trial. Lancet Diabetes Endocrinol. 2024;12:380-389. Epub 2024 Apr 30
82
https://ir.rhythmtx.com/news-releases/news-release-details/rhythmpharmaceuticals-announces-pivotal-phase-3-transcend-trial
83
van Santen HM, Denzer C, Müller HL. Could setmelanotide be the game-changer for acquired hypothalamic obesity? Front Endocrinol (Lausanne). 2024;14:1307889.
84
Roth CL, Hunneman DH, Gebhardt U, Stoffel-Wagner B, Reinehr T, Müller HL. Reduced sympathetic metabolites in urine of obese patients with craniopharyngioma. Pediatr Res. 2007;61:496-501.
85
Elfers CT, Roth CL. Effects of methylphenidate on weight gain and food intake in hypothalamic obesity. Front Endocrinol (Lausanne). 2011;2:78.
86
Mason PW, Krawiecki N, Meacham LR. The use of dextroamphetamine to treat obesity and hyperphagia in children treated for craniopharyngioma. Arch Pediatr Adolesc Med. 2002;156:887-892.
87
Hsia DS, Gosselin NH, Williams J, Farhat N, Marier JF, Shih W, Peterson C, Siegel R. A randomized, double-blind, placebo-controlled, pharmacokinetic and pharmacodynamic study of a fixed-dose combination of phentermine/topiramate in adolescents with obesity. Diabetes Obes Metab. 2020;22:480-491. Epub 2019 Dec 18
88
Huynh K, Klose M, Krogsgaard K, Drejer J, Byberg S, Madsbad S, Magkos F, Aharaz A, Edsberg B, Tfelt-Hansen J, Astrup AV, Feldt-Rasmussen U. Randomized controlled trial of Tesomet for weight loss in hypothalamic obesity. Eur J Endocrinol. 2022;186:687-700.
89
Lustig RH, Hinds PS, Ringwald-Smith K, Christensen RK, Kaste SC, Schreiber RE, Rai SN, Lensing SY, Wu S, Xiong X. Octreotide therapy of pediatric hypothalamic obesity: a double-blind, placebo-controlled trial. J Clin Endocrinol Metab. 2003;88:2586-2592.
90
Hsu EA, Miller JL, Perez FA, Roth CL. Oxytocin and Naltrexone Successfully Treat Hypothalamic Obesity in a Boy Post-Craniopharyngioma Resection. J Clin Endocrinol Metab. 2018;103:370-375.
91
Bretault M, Boillot A, Muzard L, Poitou C, Oppert JM, Barsamian C, Gatta B, Müller H, Weismann D, Rottembourg D, Inge T, Veyrie N, Carette C, Czernichow S. Clinical review: Bariatric surgery following treatment for craniopharyngioma: a systematic review and individual-level data meta-analysis. J Clin Endocrinol Metab. 2013;98:2239-2246. Epub 2013 Mar 26
92
Müller HL. Bariatric Interventions in Craniopharyngioma Patients-Best Choice or Last Option for Treatment of Hypothalamic Obesity? J Clin Endocrinol Metab. 2022;107:e426-e428.
93
Styne DM, Arslanian SA, Connor EL, Farooqi IS, Murad MH, Silverstein JH, Yanovski JA. Pediatric Obesity-Assessment, Treatment, and Prevention: An Endocrine Society Clinical Practice Guideline. J Clin Endocrinol Metab. 2017;102:709-757.
94
Eveslage M, Calaminus G, Warmuth-Metz M, Kortmann RD, Pohl F, Timmermann B, Schuhmann MU, Flitsch J, Faldum A, Müller HL. The Postopera tive Quality of Life in Children and Adolescents with Craniopharyngioma. Dtsch Arztebl Int. 2019;116:321-328.
95
Bogusz A, Boekhoff S, Warmuth-Metz M, Calaminus G, Eveslage M, Müller HL. Posterior hypothalamus-sparing surgery improves outcome after childhood craniopharyngioma. Endocr Connect. 2019;8:481-492.
96
Müller HL. Paediatrics: surgical strategy and quality of life in craniopharyngioma. Nat Rev Endocrinol. 2013;9:447-449. Epub 2013 Jun 25
97
Müller HL, Reichel J, Boekhoff S, Warmuth-Metz M, Eveslage M, Peng J, Flitsch J. Low concordance between surgical and radiological assessment of degree of resection and treatment-related hypothalamic damage: results of KRANIOPHARYNGEOM 2007. Pituitary. 2018;21:371-378.
98
Müller HL. Craniopharyngioma - What’s next. Pituitary. 2025;28:125.
99
van Roessel IMAA, de Graaf JP, Biermasz NR, Charmandari E, van Santen HM. Acquired hypothalamic dysfunction in childhood: ‘what do patients need?’ - an Endo-ERN survey. Endocr Connect. 2023;12:e230147.
100
Niel KA, Klages KL, Merchant TE, Wise MS, Hancock D, Caples M, Mandrell BN, Conklin HM, Crabtree VM. Impact of sleep, neuroendocrine, and executive function on health-related quality of life in young people with craniopharyngioma. Dev Med Child Neurol. 2021;63:984-990. Epub 2021 Mar 22
101
Craven M, Crowley JH, Chiang L, Kline C, Malbari F, Hocking MC, McCormack SE. A Survey of Patient-Relevant Outcomes in Pediatric Craniopharyngioma: Focus on Hypothalamic Obesity. Front Endocrinol (Lausanne). 2022;13:876770.
102
Aldave G, Okcu MF, Chintagumpala M, Ruggieri L, Minard CG, Malbari F, Mash LE, Paulino AC, McGovern S, Ramaswamy U, Whitehead W, Kahalley LS. Comparison of neurocognitive and quality-of-life outcomes in pediatric craniopharyngioma patients treated with partial resection and radiotherapy versus gross-total resection only. J Neurosurg Pediatr. 2023;31:453-462.
103
Kayadjanian N, Hsu EA, Wood AM, Carson DS. Caregiver Burden and Its Relationship to Health-Related Quality of Life in Craniopharyngioma Survivors. J Clin Endocrinol Metab. 2023;109:e76-e87.
104
Sowithayasakul P, Beckhaus J, Boekhoff S, Friedrich C, Calaminus G, Müller HL. Vision-related quality of life in patients with childhood-onset craniopharyngioma. Sci Rep. 2023;13:19599.
105
Friedrich C, Boekhoff S, Bischoff M, Beckhaus J, Sowithayasakul P, Calaminus G, Eveslage M, Valentini C, Bison B, Harrabi SB, Krause M, Timmermann B, Müller HL. Outcome after proton beam therapy versus photon-based radiation therapy in childhood-onset craniopharyngioma patients-results of KRANIOPHARYNGEOM 2007. Front Oncol. 2023;13:1180993.
106
Baqai MWS, Shah Z, Malik MJA, Zia N, Shafqat S, Zahid N, Shamim MS. Quality of life of pediatric patients with craniopharyngioma: A retrospective series from a low-middle-income country with more than 4 years follow-up. Surg Neurol Int. 2024;15:199.
107
Mandrell BN, Guo Y, Li Y, Hancock D, Caples M, Ashford JM, Merchant TE, Conklin HM, Crabtree VM. Internalizing Symptoms and Their Impact on Patient-Reported Health-Related Quality of Life and Fatigue among Patients with Craniopharyngioma During Proton Radiation Therapy. Children (Basel). 2024;11:1159.
108
Pereira Neto B, Pais Cunha I, Leite-Almeida AL, Ferreira S, Coelho J, Lago R, Pereira J, Gil-da-Costa MJ, Almeida P, Castro-Correia C. Quality of Life and Hormonal Impairment in Pediatric Patients With Craniopharyngiomas. Cureus. 2024;16:e52621.
109
Pérez-Torres Lobato MR, Morell M, Solano-Páez P, Ortiz-Palacios M, Menárgez Á, Panesso M, Vázquez-Gómez F, Moreno-Carrasco J, Lassaletta Á, Santa-María V, Pavon-Mengual M, Quiroga E, García-Ariza MA, Mora-Matilla M, Garrido-Colino C, Verdú-Amoros J, Nova-Lozano C, Vieito M, Cordero-Asanza EX, Clemente M, Ramos-Albiat M, de Las Morenas-Iglesias J, Moreno L, Llort A. Long-term sequelae and quality of life after childhood-onset craniopharyngioma: Results of a Spanish multicenter study. Pediatr Blood Cancer. 2024;71:e31343.
110
Rose ML, Bajaj BVM, Jimenez R, Dennehy S, Allison K, Wiltsie L, Ebb D, MacDonald SM, Tarbell NJ, Yock TI. Quality of life in pediatric patients treated with adjuvant proton radiation for craniopharyngiomas. J Neurooncol. 2025;175:153-164. Epub 2025 Jun 18
111
Hamilton JK, Conwell LS, Syme C, Ahmet A, Jeffery A, Daneman D. Hypothalamic Obesity following Craniopharyngioma Surgery: Results of a Pilot Trial of Combined Diazoxide and Metformin Therapy. Int J Pediatr Endocrinol. 2011;2011:417949. Epub 2011 Mar 22
112
Gjersdal E, Larsen LB, Ettrup KS, Vestergaard P, Nielsen EH, Karmisholt JS, Müller HL, Dal J. Semaglutide as a promising treatment for hypothalamic obesity: a six-month case series on four females with craniopharyngioma. Pituitary. 2024;27:723-730. Epub 2024 Aug 1
113
Lomenick JP, Buchowski MS, Shoemaker AH. A 52-week pilot study of the effects of exenatide on body weight in patients with hypothalamic obesity. Obesity (Silver Spring). 2016;24:1222-1225. Epub 2016 May 2
114
Rakhshani N, Jeffery AS, Schulte F, Barrera M, Atenafu EG, Hamilton JK. Evaluation of a comprehensive care clinic model for children with brain tumor and risk for hypothalamic obesity. Obesity (Silver Spring). 2010;18:1768-1774. Epub 2010 Jan 7
115
Wijnen M, Olsson DS, van den Heuvel-Eibrink MM, Wallenius V, Janssen JA, Delhanty PJ, van der Lely AJ, Johannsson G, Neggers SJ. Efficacy and safety of bariatric surgery for craniopharyngioma-related hypothalamic obesity: a matched case-control study with 2 years of follow-up. Int J Obes (Lond). 2017;41:210-216. Epub 2016 Oct 31
116
Müller HL, Gebhardt U, Maroske J, Hanisch E. Long-term follow-up of morbidly obese patients with childhood craniopharyngioma after laparoscopic adjustable gastric banding (LAGB). Klin Padiatr. 2011;223:372-373. Epub 2011 Nov 3
117
Müller HL, Gebhardt U, Wessel V, Schröder S, Kolb R, Sörensen N, Maroske J, Hanisch E. First experiences with laparoscopic adjustable gastric banding (LAGB) in the treatment of patients with childhood craniopharyngioma and morbid obesity. Klin Padiatr. 2007;219:323-325.
118
Gatta B, Nunes ML, Bailacq-Auder C, Etchechoury L, Collet D, Tabarin A. Is bariatric surgery really inefficient in hypothalamic obesity? Clin Endocrinol (Oxf). 2013;78:636-638.
119
Weismann D, Pelka T, Bender G, Jurowich C, Fassnacht M, Thalheimer A, Allolio B. Bariatric surgery for morbid obesity in craniopharyngioma. Clin Endocrinol (Oxf). 2013;78:385-390.
120
Trotta M, Da Broi J, Salerno A, Testa RM, Marinari GM. Sleeve gastrectomy leads to easy management of hormone replacement therapy and good weight loss in patients treated for craniopharyngioma. Updates Surg. 2017;69:95-99. Epub 2017 Mar 4
121
Garrez I, Lapauw B, Van Nieuwenhove Y. Bariatric Surgery for Treatment of Hypothalamic Obesity After Craniopharyngioma Therapy: a Matched Case-Control Study. Obes Surg. 2020;30:2439-2444.
122
van Santen SS, Wolf P, Kremenevski N, Boguszewski CL, Beiglböck H, Fiocco M, Wijnen M, Wallenius VR, van den Heuvel-Eibrink MM, van der Lely AJ, Johannsson G, Luger A, Krebs M, Buchfelder M, Delhanty PJD, Neggers SJCMM, Olsson DS. Bariatric Surgery for Hypothalamic Obesity in Craniopharyngioma Patients: A Retrospective, Matched Case-Control Study. J Clin Endocrinol Metab. 2021;106:e4734-e4745.
123
Faucher P, Carette C, Jannot AS, Gatta-Cherifi B, Van Straaten A, Piquet MA, Raverot G, Alligier M, Batisse T, Ziegler O, Drui D, Bretault M, Farigon N, Slim K, Genser L, Poghosyan T, Vychnevskaia K, Blanchard C, Robert M, Gronnier C, Poitou C, Czernichow S. Five-Year Changes in Weight and Diabetes Status After Bariatric Surgery for Craniopharyngioma-Related Hypothalamic Obesity: a Case-Control Study. Obes Surg. 2022;32:2321-2331. Epub 2022 May 6
124
Smith DK, Sarfeh J, Howard L. Truncal vagotomy in hypothalamic obesity. Lancet. 1983;1:1330-1331.
125
Harat M, Rudaś M, Zieliński P, Birska J, Sokal P. Nucleus accumbens stimulation in pathological obesity. Neurol Neurochir Pol. 2016;50:207-210. Epub 2016 Feb 5
126
Puget S, Garnett M, Wray A, Grill J, Habrand JL, Bodaert N, Zerah M, Bezerra M, Renier D, Pierre-Kahn A, Sainte-Rose C. Pediatric craniopharyngiomas: classification and treatment according to the degree of hypothalamic involvement. J Neurosurg. 2007;106(Suppl 1):3-12.
127
de Vile CJ, Grant DB, Hayward RD, Kendall BE, Neville BG, Stanhope R. Obesity in childhood craniopharyngioma: relation to post-operative hypothalamic damage shown by magnetic resonance imaging. J Clin Endocrinol Metab. 1996;81:2734-2737.